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Literature DB >> 20149854

Mechanics of the frog ear.

Pim Van Dijk¹, Matthew J Mason, Richard L M Schoffelen, Peter M Narins, Sebastiaan W F Meenderink.

Abstract

The frog inner ear contains three regions that are sensitive to airborne sound and which are functionally distinct. (1) The responses of nerve fibres innervating the low-frequency, rostral part of the amphibian papilla (AP) are complex. Electrical tuning of hair cells presumably contributes to the frequency selectivity of these responses. (2) The caudal part of the AP covers the mid-frequency portion of the frog's auditory range. It shares the ability to generate both evoked and spontaneous otoacoustic emissions with the mammalian cochlea and other vertebrate ears. (3) The basilar papilla functions mainly as a single auditory filter. Its simple anatomy and function provide a model system for testing hypotheses concerning emission generation. Group delays of stimulus-frequency otoacoustic emissions (SFOAEs) from the basilar papilla are accounted for by assuming that they result from forward and reverse transmission through the middle ear, a mechanical delay due to tectorial membrane filtering and a rapid forward and reverse propagation through the inner ear fluids, with negligible delay.

Entities: Chemical Disease Species

Mesh：

Year: 2010 PMID： 20149854 PMCID： PMC3023005 DOI： 10.1016/j.heares.2010.02.004

Source DB: PubMed Journal: Hear Res ISSN： 0378-5955 Impact factor: 3.208

54 in total

Mechanics of the frog ear.

1. Testing coherent reflection in chinchilla: Auditory-nerve responses predict stimulus-frequency emissions.

2. Mechanics of the inner ear of the bullfrog (Rana catesbeiana): the contact membranes and the periotic canal.

3. A model for energy flow in the inner ear of the bullfrog (Rana catesbeiana).

4. Distortion product otoacoustic emissions in the tree frog Hyla cinerea.

5. Frequency matching of vocalizations to inner-ear sensitivity along an altitudinal gradient in the coqui frog.

6. Otoacoustic emissions in humans, birds, lizards, and frogs: evidence for multiple generation mechanisms.

7. Tuning of the tectorial membrane in the basilar papilla of the northern leopard frog.

Review 8. Hair cells, hearing and hopping: a field guide to hair cell physiology in the frog.

9. Vibrometric studies of the middle ear of the bullfrog Rana catesbeiana II. The operculum.

10. Vibrometric studies of the middle ear of the bullfrog Rana catesbeiana I. The extrastapes.

1. Exocytosis in the frog amphibian papilla.

2. The frog inner ear: picture perfect?

3. Recovery of otoacoustic emissions after high-level noise exposure in the American bullfrog.

4. External and middle ear sound pressure distribution and acoustic coupling to the tympanic membrane.

5. Basilar membrane and tectorial membrane stiffness in the CBA/CaJ mouse.

6. MEMRI for visualizing brain activity after auditory stimulation in frogs.

Review 7. Using Xenopus to discover new genes involved in branchiootorenal spectrum disorders.

8. Pa2G4 is a novel Six1 co-factor that is required for neural crest and otic development.

9. Sex differences and endocrine regulation of auditory-evoked, neural responses in African clawed frogs (Xenopus).

Review 10. Changes in the adult vertebrate auditory sensory epithelium after trauma.